Inhibition of EREG/ErbB/ERK by Astragaloside IV reversed taxol-resistance of non-small cell lung cancer through attenuation of stemness via TGFβ and Hedgehog signal pathway.

IF 6.6 2区医学 Q1 Medicine

Cellular Oncology Pub Date : 2024-10-07 DOI:10.1007/s13402-024-00999-7

Wenhao Xiu, Yujia Zhang, Dongfang Tang, Sau Har Lee, Rui Zeng, Tingjie Ye, Hua Li, Yanlin Lu, Changtai Qin, Yuxi Yang, Xiaofeng Yan, Xiaoling Wang, Xudong Hu, Maoquan Chu, Zhumei Sun, Wei Xu

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引用次数: 0

Abstract

Purpose: Taxol is the first-line chemo-drug for advanced non-small cell lung cancer (NSCLC), but it frequently causes acquired resistance, which leads to the failure of treatment. Therefore, it is critical to screen and characterize the mechanism of the taxol-resistance reversal agent that could re-sensitize the resistant cancer cells to chemo-drug.

Method: The cell viability, sphere-forming and xenografts assay were used to evaluate the ability of ASIV to reverse taxol-resistance. Immunohistochemistry, cytokine application, small-interfering RNA, small molecule inhibitors, and RNA-seq approaches were applied to characterize the molecular mechanism of inhibition of epiregulin (EREG) and downstream signaling by ASIV to reverse taxol-resistance.

Results: ASIV reversed taxol resistance through suppression of the stemness-associated genes of spheres in NSCLC. The mechanism exploration revealed that ASIV promoted the K48-linked polyubiquitination of EREG along with degradation. Moreover, EREG could be triggered by chemo-drug treatment. Consequently, EREG bound to the ErbB receptor and activated the ERK signal to regulate the expression of the stemness-associated genes. Inhibition of EREG/ErbB/ERK could reverse the taxol-resistance by inhibiting the stemness-associated genes. Finally, it was observed that TGFβ and Hedgehog signaling were downstream of EREG/ErbB/ERK, which could be targeted using inhibitors to reverse the taxol resistance of NSCLC.

Conclusions: These findings revealed that inhibition of EREG by ASIV reversed taxol-resistance through suppression of the stemness of NSCLC via EREG/ErbB/ERK-TGFβ, Hedgehog axis.

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黄芪皂苷IV通过TGFβ和刺猬信号通路抑制EREG/ErbB/ERK，从而逆转了非小细胞肺癌对紫杉醇的耐药性。

目的：紫杉醇是治疗晚期非小细胞肺癌（NSCLC）的一线化疗药物，但它经常引起获得性耐药性，导致治疗失败。因此，筛选并鉴定可使耐药癌细胞对化疗药物重新敏感的紫杉醇耐药性逆转剂的机制至关重要：方法：采用细胞活力、成球和异种移植试验评估 ASIV 逆转紫杉醇耐药性的能力。免疫组化、细胞因子应用、小干扰RNA、小分子抑制剂和RNA-seq等方法被用于表征ASIV抑制epiregulin（EREG）和下游信号转导以逆转taxol耐药性的分子机制：结果：ASIV通过抑制NSCLC中球形细胞的干性相关基因逆转了紫杉醇耐药。机制探索发现，ASIV促进了EREG的K48连接多泛素化和降解。此外，化疗药物也会触发EREG。因此，EREG与ErbB受体结合并激活ERK信号，从而调控干性相关基因的表达。抑制EREG/ErbB/ERK可抑制干性相关基因，从而逆转对紫杉醇的耐药性。最后，研究人员观察到，TGFβ和刺猬信号是EREG/ErbB/ERK的下游，可以使用抑制剂来逆转NSCLC对紫杉醇的耐药性：这些研究结果表明，ASIV抑制EREG可通过EREG/ErbB/ERK-TGFβ和Hedgehog轴抑制NSCLC的干性，从而逆转紫杉醇耐药性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Cellular Oncology Biochemistry, Genetics and Molecular Biology-Cancer Research

CiteScore

10.40

自引率

1.50%

发文量

审稿时长

16 weeks

期刊介绍： The Official Journal of the International Society for Cellular Oncology Focuses on translational research Addresses the conversion of cell biology to clinical applications Cellular Oncology publishes scientific contributions from various biomedical and clinical disciplines involved in basic and translational cancer research on the cell and tissue level, technical and bioinformatics developments in this area, and clinical applications. This includes a variety of fields like genome technology, micro-arrays and other high-throughput techniques, genomic instability, SNP, DNA methylation, signaling pathways, DNA organization, (sub)microscopic imaging, proteomics, bioinformatics, functional effects of genomics, drug design and development, molecular diagnostics and targeted cancer therapies, genotype-phenotype interactions. A major goal is to translate the latest developments in these fields from the research laboratory into routine patient management. To this end Cellular Oncology forms a platform of scientific information exchange between molecular biologists and geneticists, technical developers, pathologists, (medical) oncologists and other clinicians involved in the management of cancer patients. In vitro studies are preferentially supported by validations in tumor tissue with clinicopathological associations.